Lens barrel and optical apparatus

ABSTRACT

A lens barrel, in one configuration, includes a moving member that has a cam pin and moves in an optical axis direction of a lens while holding the lens; a first barrel; a second barrel; a recess groove that is formed along a circumferential direction around the optical axis in one of a surface, which faces the first barrel, of the second barrel and a surface, which faces the second barrel, of the first barrel; and a biasing portion that faces the recess groove and applies a biasing force in a direction intersecting with the optical axis. The biasing force applied by the biasing portion changes according to a relative rotation between the first barrel and the second barrel.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of U.S. application Ser. No.14/991,636, filed on Jan. 8, 2016, which is a continuation of U.S.patent application Ser. No. 14/000,585, filed on Dec. 11, 2013, which isa U.S. national stage application of PCT/JP2012/056272 filed Mar. 12,2012 and claims foreign priority benefit of Japanese Application No.2011-064654 filed Mar. 23, 2011 in the Japanese Intellectual PropertyOffice, the contents of each of which are incorporated herein byreference.

BACKGROUND 1. Field

The present invention relates to a lens barrel and an optical apparatus.

2. Related Art

To allow a user to operate a zooming ring of a lens barrel with constantoperating torque without feeling play, there has been conventionallysuggested a method that arranges rubber member between the zooming ringand a fixed barrel to bias the zooming ring simultaneously in theoptical axis direction and the radial direction of the zooming ring (seePatent Document 1, for example).

Patent Document 1: Japanese Patent Application Publication No.2009-169232

SUMMARY

However, in Patent Document 1, constant biasing force is exerted on thezooming ring with the elastic member at all times. Thus, when thetechnique of Patent Document 1 is applied to a lens barrel in whichforce (resisting force) exerted against the zooming ring during therotation of the zooming ring depends on a position of the zooming ring(an angle to the fixed barrel), a user may fail to operate the zoomingring with constant operating torque.

The present invention has been made in the view of the above problems,and has an objective to provide a lens barrel and an optical apparatusthat are capable of reducing a change in operating torque.

The lens barrel of the present invention is a lens barrel including: afirst barrel in which a cam groove having a shape curved with respect toa predetermined axis direction is formed to pierce through the firstbarrel; a second barrel capable of rotating around the predeterminedaxis along an outer circumferential surface of the first barrel, astraight groove extending in the predetermined axis direction beingformed in the second barrel; a moving member that has a cam pin movingalong the cam groove and the straight groove and moves in thepredetermined axis direction while holding a lens inside the firstbarrel as the second barrel rotates with respect to the first barrel;and a damping mechanism that applies damping force depending on an angleof the cam groove to the predetermined axis direction to the secondbarrel.

Alternatively, the lens barrel of the present invention is a lens barrelincluding: a first barrel in which a straight groove extending in apredetermined axis direction is formed to pierce through the firstbarrel; a second barrel capable of rotating around the predeterminedaxis along an outer circumferential surface of the first barrel, a camgroove having a shape curved with respect to the predetermined axisdirection being formed in the second barrel; a moving member that has acam pin moving along the straight groove and the cam groove and moves inthe predetermined axis direction while holding a lens inside the firstbarrel as the second barrel rotates with respect to the first barrel;and a damping mechanism that applies damping force depending on an angleof the cam groove to the predetermined axis direction to the secondbarrel.

In the aforementioned cases, the damping mechanism may include acontacting member that is provided in the outer circumferential surfaceof the first barrel and makes contact with at least a part of an innercircumferential surface of the second barrel, and the contacting membermay have a contacting/non-contacting state with the innercircumferential surface of the second barrel that is changed inaccordance with a position of the cam pin in the cam groove.

In addition, the damping mechanism may include a contacting member thatis provided in an inner circumferential surface of the second barrel andmakes contact with at least a part of the outer circumferential surfaceof the first barrel, and the contacting member may have acontacting/non-contacting state with the outer circumferential surfaceof the first barrel that is changed in accordance with a position of thecam pin in the cam groove.

In addition, the damping mechanism may include a contacting member thatis provided in the outer circumferential surface of the first barrel andmakes contact with at least a part of an inner circumferential surfaceof the second barrel, and the contacting member may make contact withone of regions with different friction coefficients in the innercircumferential surface of the second barrel in accordance with aposition of the cam pin in the cam groove. In addition, the dampingmechanism may include a contacting member that is provided in an innercircumferential surface of the second barrel and makes contact with atleast a part of the outer circumferential surface of the first barrel,and the contacting member may make contact with one of regions havingdifferent friction coefficients provided in the outer circumferentialsurface of the first barrel in accordance with a position of the cam pinin the cam groove.

In addition, the contacting member may be urged by force directed towarda plane facing the contacting member at all times.

The optical apparatus of the present invention includes the lens barrelof the present invention.

The lens barrel and the optical apparatus of the present invention haveeffects that a change in operating torque can be reduced.

Additional aspects and/or advantages will be set forth in part in thedescription which follows and, in part, will be apparent from thedescription, or may be learned by practice of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

These and/or other aspects and advantages will become apparent and morereadily appreciated from the following description of the embodiments,taken in conjunction with the accompanying drawings of which:

FIG. 1 is a partly cross-sectional view illustrating a structure of acamera in accordance with an embodiment;

FIG. 2A is a diagram illustrating the movement of a cam pin in a camgroove when a zooming ring is rotated with respect to a fixed barrel,FIG. 2B is a diagram illustrating the movement of the cam pin in astraight groove, and FIG. 2C is a diagram superimposing FIG. 2A on FIG.2B;

FIG. 3 is a cross-sectional view of a barrel portion;

FIG. 4 is a cross-sectional view of the barrel portion and the fixedbarrel taken along a plane including a recess groove;

FIG. 5A and FIG. 5B are diagrams illustrating a relationship between aspring member and the recess groove when the zooming ring (barrelportion) is rotated with respect to the fixed barrel (No. 1);

FIG. 6 is a diagram illustrating a relationship between the springmember and the recess groove when the zooming ring (barrel portion) isrotated with respect to the fixed barrel (No. 2); and

FIG. 7 is a diagram illustrating a camera in accordance with a variationof the embodiment.

DESCRIPTION OF EMBODIMENTS

Reference will now be made in detail to the embodiments, examples ofwhich are illustrated in the accompanying drawings, wherein likereference numerals refer to the like elements throughout. Theembodiments are described below to explain the present invention byreferring to the figures.

Hereinafter, a description will be given of an exemplary embodiment withreference to FIG. 1 through FIG. 6. FIG. 1 is a partly cross-sectionalview schematically illustrating a structure of a camera 100 inaccordance with the exemplary embodiment.

The camera 100 includes a camera body 200 and a lens barrel 300. Thecamera body 200 includes a chassis, and various optical systems, animaging element, and a shutter housed in the chassis. A part of thechassis of the camera body 200 has a camera mount. The camera mount canengage with a lens mount 50 of the lens barrel 300. The camera mount andthe lens mount 50 are, for example, bayonet mounts.

The lens barrel 300 includes a first lens group L1, a second lens groupL2, and a third lens group L3 arranged in this order from a subject side(the opposite side to the camera body 200). The positional relationshipamong the lens groups is adjusted so that their optical axes AX comeinto line.

The lens barrel 300 includes a second lens group supporting frame 12that supports the second lens group L2, a fixed barrel 15 that isconfigured not to be capable of rotating or moving with respect to thelens mount 50 (and the camera body 200), an outer barrel 22 that isfixed to the lens mount 50 and arranged outside of the fixed barrel 15,and a zooming ring 20 that is configured to be capable of rotatingaround the optical axis AX with respect to the outer barrel 22 and thefixed barrel 15.

The lens barrel 300 also includes supporting frames that support thefirst lens group L1 and the third lens group L3 thereinside, but theillustration thereof is omitted for convenience sake in illustration andexplanation. The supporting frame of the first lens group L1 is fixedto, for example, the inner circumferential surface of the fixed barrel15 at the subject side while the supporting frame of the third lensgroup L3 is fixed, for example, to the inside of the lens mount 50. Thelens barrel 300 further includes other mechanisms and structures such asa diaphragm mechanism, but the illustration thereof is also omitted.

The second lens group supporting frame 12 is a substantially cylindricalmember supporting the second lens group L2, and has an outercircumferential surface including a cam pin 19 protruding.

A cam groove 15 a having a shape curved with respect to the optical axisAX direction (spiral shape) (see FIG. 2A) is formed in the fixed barrel15 so as to pierce through the fixed barrel 15. The cam pin 19 engageswith the cam groove 15 a. The reason why the cam groove 15 a is curvedis because the travel distance of the lens group (the second lens groupL2 in the present embodiment) is long while the rotating angle of thezooming ring 20 with respect to the fixed barrel 15 is limited to acertain angle in a high-power zoom lens having a zoom ratio of five ormore.

The zooming ring 20 includes an operating portion 18 and a barrelportion 17. The operating portion 18 is fixed to the barrel portion 17by a pin or the like. The zooming ring 20 rotates around the opticalaxis AX in a state of the inner circumferential surface of the barrelportion 17 following the outer circumferential surface of the fixedbarrel 15.

The operating portion 18 has an outer circumferential surface anti-slipfinished by rubber or the like. A straight groove 17 a extending in theoptical axis direction is formed in the barrel portion 17 so as topierce through the barrel portion 17 (see FIG. 3). The cam pin 19engages with the straight groove 17 a. That is to say, the cam pin 19 isinserted into a place where the cam groove 15 a intersects with thestraight groove 17 a (see FIG. 2C). The straight groove 17 a may be arecess groove not piercing through the barrel portion 17.

FIG. 1 illustrates only one cam pin 19, but two or more cam pins 19 maybe provided on the outer circumferential surface of the second lensgroup supporting frame 12. When two or more cam pins 19 are provided, acorresponding number of cam grooves 15 a are formed in the fixed barrel15, and a corresponding number of straight grooves 17 a are formed inthe barrel portion 17.

FIG. 2A is a diagram illustrating the movement of the cam pin 19 in thecam groove 15 a when the zooming ring 20 is rotated with respect to thefixed barrel 15, and FIG. 2B is a diagram illustrating the movement ofthe cam pin 19 in the straight groove 17 a. FIG. 2C is a diagramsuperimposing FIG. 2A on FIG. 2B. These diagrams demonstrate that thecam pin 19 engaging with the straight groove 17 a moves in the rotationdirection together with the zooming ring 20. The cam pin 19, however,also engages with the cam groove 15 a and thus moves through thestraight groove 17 a along the optical axis AX direction while moving inthe rotation direction. This allows the second lens group L2 to move inthe optical axis AX direction (zooming operation) as the zooming ring 20rotates.

As illustrated in FIG. 2A through FIG. 2C, the zooming ring 20 canrotate from the wide side to the tele side with respect to the fixedbarrel 15 within a range of angles (θ1+θ2+θ3). In this case, when thezooming ring 20 is rotated within a range of angles θ1 near the wideside or a range of angles θ3 near the tele side, the difference betweenthe angle of the cam groove 15 a (the moving direction of the cam pin19) and the rotation direction of the zooming ring 20 is small, and thusthe cam pin 19 is subjected to low force from the cam groove 15 a whenmoving in the rotation direction. Thus, the cam pin 19 easily movesthrough the cam groove 15 a. In the present embodiment, the cam pin 19moves more easily within the range of angles θ3 than within the range ofangles θ1. On the other hand, when the zooming ring 20 is rotated withina range of angles θ2, which is the middle between the tele side and thewide side, the difference between the angle of the cam groove 15 a (themoving direction of the cam pin 19) and the rotation direction of thezooming ring 20 is large, and thus the cam pin 19 is subjected to highforce from the cam groove 15 a when moving in the rotation direction.Thus, the cam pin 19 has difficulty in moving through the cam groove 15a.

As demonstrated by FIG. 3 cross-sectionally illustrating the barrelportion 17, the present embodiment forms a recess groove 21 in thebarrel portion 17 in addition to the straight groove 17 a. The recessgroove 21 is formed in the inner circumferential surface of the barrelportion 17 along the circumferential direction.

FIG. 4 is a cross-sectional view of the barrel portion 17 and the fixedbarrel 15 taken along a plane crossing the recess groove 21 and beingperpendicular to the optical axis AX. As illustrated in FIG. 4, therecess groove 21 has a region with a distance in the radial directionfrom the optical axis AX of R1, a region with a distance of R2 (>R1),and a region with a distance of R3 (<R1<R2).

In the recess groove 21, the region with a distance from the opticalaxis AX of R1 is a region within which the cam pin 19 faces thereference point of the fixed barrel 15 (described as a point P) whenmoving within the range of angles θ1 of the cam groove 15 a, andcorresponds to the range of angles θ1. Moreover, the region with adistance from the optical axis AX of R2 in the recess groove 21 is aregion within which the cam pin 19 faces the reference point (point P)of the fixed barrel 15 when moving within the range of angles θ2 of thecam groove 15 a, and corresponds to the range of angles θ2. Further, theregion with a distance from the optical axis AX of R3 in the recessgroove 21 is a region within which the cam pin 19 faces the referencepoint (point P) of the fixed barrel 15 when moving within the range ofangles θ3 of the cam groove 15 a, and corresponds to the range of anglesθ3. The region with a distance of R1 smoothly transitions to the regionwith a distance of R2 and the region with a distance of R2 smoothlytransitions to the region with a distance of R3. Thus, the distancesmoothly changes.

The present embodiment provides a spring member 23 at a position facingthe recess groove 21 of the fixed barrel 15 (the position of the pointP) as illustrated in FIG. 4. The spring member 23 is an arc-curved leafspring or the like, and has elastic force in the radial direction of thefixed barrel 15. That is to say, while the spring member 23 is incontact with the recess groove 21 (the inner circumferential surface ofthe barrel portion 17), the spring member 23 exerts outward biasingforce in the radial direction of the barrel portion 17 on the recessgroove 21.

A description will next be given of a relationship between the springmember 23 and the recess groove 21 when the zooming ring 20 (the barrelportion 17) is rotated with respect to the fixed barrel 15 withreference to FIG. 5A, FIG. 5B, and FIG. 6.

FIG. 5B illustrates a relationship between the barrel portion 17 and thefixed barrel 15 when the second lens group L2 is located in the middlebetween the wide side and the tele side, i.e. when the point P islocated within the range of angles θ2. In the state illustrated in FIG.5B, the spring member 23 is in slightly contact with the recess groove21, and the spring member 23 exerts biasing force F2 (<F1) on the barrelportion 17. That is to say, the biasing force F2 acts as damping force(braking force) exerted against the zooming ring 20 rotated within therange of angles θ2.

FIG. 6 illustrates a relationship between the barrel portion 17 and thefixed barrel 15 when the second lens group L2 is located at the teleside, i.e. when the point P is located within the range of angles θ3. Inthe state illustrated in FIG. 6, the spring member 23 is in contact withthe recess groove 21. Here, the distance R3 is less than the distanceR1, and thus the spring member 23 exerts biasing force F3 (>F1>F2) onthe barrel portion 17. That is to say, the biasing force F3 acts asdamping force (breaking force) exerted against the zooming ring 20rotated from the tele side within the range of angles θ3.

The biasing force (damping force) exerted on the barrel portion 17 fromthe spring member 23 gradually changes near the boundary between theangles θ1 and θ2 and the boundary between the angles θ2 and θ3.

As described above, in the present embodiment, the biasing force(damping force) exerted on the barrel portion 17 from the spring member23 is low when the force necessary to rotate the zooming ring 20 is high(when the point P1 is within the range of angles θ2) while the biasingforce (damping force) (F1, F3) exerted on the barrel portion 17 from thespring member 23 is high when the force necessary to rotate the zoomingring 20 is low (when the point P is within the range of angles θ1 orθ3). Therefore, the change in the operating torque necessary to rotatethe zooming ring 20 (uneven torque) can be reduced, and thus it becomespossible to make the operating torque approximately constant bydesigning the shape of the recess groove 21 according to the shape ofthe cam groove 15 a.

As described above in detail, the present embodiment configures the camgroove 15 a, which has a shape curved with respect to the optical axisAX direction, to be formed in the fixed barrel 15 so as to piercethrough the fixed barrel 15, configures the zooming ring 20 (barrelportion 17) to be capable of rotating around the optical axis AX alongthe outer circumferential surface of the fixed barrel 15 and have thestraight groove 17 a formed therein, and configures the second lensgroup supporting frame 12, which supports the lenses inside the fixedbarrel 15, to have the cam pin 19 moving along the cam groove 15 a andthe straight groove 17 a and move in the optical axis AX direction asthe zooming ring 20 (barrel portion 17) is rotated with respect to thefixed barrel 15, the straight groove 17 a extending in the optical axisAX direction. In addition, the spring member 23 applies the biasingforce (damping force) depending on the angle of the cam groove 15 a tothe optical axis AX direction to the barrel portion 17. Thisconfiguration enables to reduce the change in the operating torquenecessary to rotate the zooming ring 20 by applying the biasing force(damping force) depending on the angle of the cam groove 15 a to theoptical axis AX direction to the zooming ring 20 (the barrel portion 17)from the spring member 23 even though movability of the cam pin 19through the cam groove 15 a changes in accordance with the angle of thecam groove 15 a to the optical axis AX direction as described in thepresent embodiment. Therefore, the operational feeling is improved, andthe zooming operation becomes easy.

The present embodiment can apply the damping force depending on theangle of the cam groove 15 a, which engages with the cam pin 19, to theoptical axis AX direction with a simple structure having the springmember 23 provided in the fixed barrel 15 and the recess groove 21formed in the barrel portion 17, and thus, can reduce the increase ofproduction cost and production process, and improve the operationfeeling of the zooming ring 20.

The aforementioned embodiment three-step changes the distance from theoptical axis of the recess groove 21, but does not intend to suggest anylimitation. The distance of the recess groove 21 from the optical axismay be multiple-step changed or seamlessly changed according to theangle of the cam groove to the optical axis. Moreover, theaforementioned embodiment contacts the spring member 23 with the recessgroove 21 at all times, but does not intend to suggest any limitation,and the spring member 23 may be in non-contact with the recess groove 21in part.

The aforementioned embodiment provides the spring member 23 in the fixedbarrel 15 and forms the recess groove 21 in the barrel portion 17 of thezooming ring 20, but does not intend to suggest any limitation, and mayprovide the spring member 23 in the barrel portion 17 and form therecess groove 21 in the outer circumferential surface of the fixedbarrel 15. This structure also has the same advantage as that of theaforementioned embodiment.

The aforementioned embodiment provides the spring member 23 in the fixedbarrel 15 to exert the biasing force on the barrel portion 17, but doesnot intend to suggest any limitation, and may use other members capableof exerting the biasing force (e.g. an elastic member such as rubber)instead of the spring member 23.

The aforementioned embodiment changes the damping force exerted on thebarrel portion 17 (zooming ring) from the spring member 23 by change ofthe contacting state between the spring member 23 and the recess groove21, but does not intend to suggest any limitation. For example, thefixed barrel 15 may have a contacting member that makes contact with thebarrel portion 17, and the inner circumferential surface of the barrelportion 17 that is to be in contact with the contacting member mayinclude regions with different friction coefficients (regions havingdifferent surface roughness) that change frictional force generated bythe contact of the contacting member. In this case, the frictioncoefficient (surface roughness) is determined based on the angle of thecam groove at which the cam pin 19 is positioned (the angle to theoptical axis AX direction). The above-described structure can also havethe same advantage as that of the aforementioned embodiment. Also inthis case, the contacting member may be provided in the barrel portion17, and surfaces with different friction coefficients may be provided tothe fixed barrel 15.

The aforementioned embodiment describes a lens barrel including thesecond lens group L2 that rotates as the zooming ring 20 rotates, butdoes not intend to suggest any limitation. For example, a cylindricalmember may be arranged between the second lens group supporting frame 12and the fixed barrel 15 so that the second lens group L2 does notrotate. In this case, the second lens group L2 can move in the opticalaxis direction without rotating when a groove engaging with the cam pin19 and extending in the rotation direction (circumferential direction)around the optical axis is formed in the inner circumferential surfaceof the cylindrical member and a cam pin engaging with the cam groove 15a and the straight groove 17 a is provided in the outer circumferentialsurface.

The aforementioned embodiment forms the straight groove 17 a in thebarrel portion 17 of the zooming ring 20 and forms the cam groove 15 ain the fixed barrel 15, but does not intend to suggest any limitation.As illustrated in FIG. 7, the cam groove 15 a may be formed in thebarrel portion 17 while the straight groove 17 a is formed in the fixedbarrel 15.

The aforementioned embodiment describes only one example of thestructure of the lens barrel 300. Thus, various structures may beapplied to the structure of a lens barrel.

While the exemplary embodiments of the present invention have beenillustrated in detail, the present invention is not limited to theabove-mentioned embodiments, and other embodiments, variations andmodifications may be made without departing from the scope of thepresent invention.

Although a few embodiments have been shown and described, it would beappreciated by those skilled in the art that changes may be made inthese embodiments without departing from the principles and spirit ofthe invention, the scope of which is defined in the claims and theirequivalents.

What is claimed is:
 1. A lens barrel comprising: a moving member thathas a cam pin and moves in an optical axis direction of a lens whileholding the lens; a first barrel in which a first groove that engageswith the cam pin and has a curved part that is curved with respect tothe optical axis direction is formed; a second barrel that is arrangedso as to face an outer circumferential surface or inner circumferentialsurface of the first barrel and is capable of rotating around theoptical axis relative to the first barrel; a second groove that isformed along the optical axis in the second barrel and engages with thecam pin; a recess groove that is formed along a circumferentialdirection around the optical axis in one of a surface, which faces thefirst barrel, of the second barrel and a surface, which faces the secondbarrel, of the first barrel; and a biasing portion that faces the recessgroove and applies a biasing force in a direction intersecting with theoptical axis, wherein the biasing force applied by the biasing portionchanges according to a relative rotation between the first barrel andthe second barrel.
 2. The lens barrel according to claim 1, wherein therecess groove is formed in the surface, which faces the first barrel, ofthe second barrel.
 3. The lens barrel according to claim 2, wherein therecess groove is formed so as to overlap with a part of the secondgroove in the optical axis direction.
 4. The lens barrel according toclaim 1, wherein a part of the second groove is formed on acircumferential surface on which the recess groove is formed.
 5. Thelens barrel according to claim 1, wherein a first end of the secondgroove is positioned on a circumferential surface on which the recessgroove is formed.
 6. The lens barrel according to claim 1, wherein therecess groove has a contact surface that is in contact with the biasingportion, and a distance between a position at which the contact surfaceand the biasing portion are in contact with each other and the opticalaxis differs depending on a position of the biasing portion with respectto the contact surface in a circumferential direction.
 7. The lensbarrel according to claim 6, wherein a shape of the contact surfacediffers depending on a shape of the curved part.
 8. The lens barrelaccording to claim 1, wherein the biasing portion is provided to thefirst barrel, and is in contact or non-contact with the second barreldepending on a position in a circumferential direction.
 9. The lensbarrel according to claim 1, further comprising: a zooming ring that isfixed to one of the first barrel and the second barrel and is operatedby a user, wherein an amount of rotation of the one of the first barreland the second barrel is equal to an amount of rotation of the zoomingring.
 10. The lens barrel according to claim 9, further comprising: alens mount that is fixed to another of the first barrel and the secondbarrel and is engaged with a camera body, wherein the another of thefirst barrel and the second barrel is arranged in an inner circumferencesurface of the another of the first barrel and the second barrel. 11.The lens barrel according to claim 1, wherein the recess groove and thebiasing portion are always in contact with each other during a zoomingoperation from a wide-side end to a tele-side end.
 12. The lens barrelaccording to claim 1, wherein the curved portion of the first groove hasa shape that causes an inclination direction with respect to the opticalaxis to be opposite in the optical axis direction in a process of azooming operation, and a distance of the recess groove from the opticalaxis continuously changes in the process of the zooming operation. 13.The lens barrel according to claim 1, wherein a width of a first region,in which a greatest force is applied to the cam pin from the firstgroove, in a rotation direction is less than a sum of widths of secondregions, in each of which a less force is applied to the cam pin fromthe first groove, in the rotation direction.
 14. The lens barrelaccording to claim 1, wherein a zoom ratio is five or more.
 15. Anoptical apparatus comprising: a lens barrel including: a moving memberthat has a cam pin and moves in an optical axis direction of a lenswhile holding the lens; a first barrel in which a first groove thatengages with the cam pin and has a curved part that is curved withrespect to the optical axis direction is formed; a second barrel that isarranged so as to face an outer circumferential surface or innercircumferential surface of the first barrel and is capable of rotatingaround the optical axis relative to the first barrel; a second groovethat is formed along the optical axis in the second barrel and engageswith the cam pin; a recess groove that is formed along a circumferentialdirection around the optical axis in one of a surface, which faces thefirst barrel, of the second barrel and a surface, which faces the secondbarrel, of the first barrel; and a biasing portion that faces the recessgroove and applies a biasing force in a direction intersecting with theoptical axis, wherein the biasing force applied by the biasing portionchanges according to a relative rotation between the first barrel andthe second barrel.
 16. A method of producing a lens barrel, the methodcomprising: providing a moving member that has a cam pin and moves in anoptical axis direction of a lens while holding the lens; providing afirst barrel in which a first groove that engages with the cam pin andhas a curved part that is curved with respect to the optical axisdirection is formed; providing a second barrel so that the second barrelis arranged so as to face an outer circumferential surface or innercircumferential surface of the first barrel and is capable of rotatingaround the optical axis relative to the first barrel; providing a secondgroove that is formed along the optical axis in the second barrel andengages with the cam pin; providing a recess groove that is formed alonga circumferential direction around the optical axis in one of a surface,which faces the first barrel, of the second barrel and a surface, whichfaces the second barrel, of the first barrel; and providing a biasingportion that faces the recess groove and applies a biasing force in adirection intersecting with the optical axis so that the biasing forceapplied by the biasing portion changes according to a relative rotationbetween the first barrel and the second barrel.